RU2187145C2 - Computer in the form of fountain-pen - Google Patents

Abstract

FIELD: portable computers; telephone directory control devices. SUBSTANCE: computer made in the form of fountain-pen has in addition telephone directory storage unit, telephone directory control facility, mouse mode operation unit, communication unit, and keyboard mode operation unit. EFFECT: new application of computer. 23 cl, 16 dwg

Description

 The invention relates to a computer held in hand, in particular to a computer in the form of a fountain pen, which can be used as a calculator, a telephone directory control device and as an electronic dictionary.

 Currently, address books and organizing notebooks are used so that they can record contact information about a client and acquaintances. However, until the information is recorded accurately and in order, the search for the required contact information using ordinary address books and organizing notebooks will not be quite simple.

 Most electronic dictionaries and personal digital assistants (PCs) now also contain numerous additional functions, such as calculation functions, functions of an organizer of work planning and functions of managing a telephone directory, thus expanding the possibilities of their application. However, these electronic devices are still relatively voluminous and heavy, which leads to certain inconvenience when worn.

 Known, in addition, is disclosed in RU 2073907 A computer in the form of a fountain pen, containing an elongated cylindrical body, having a writing end, equipped with a rotating ball stop serving as a writing unit of a fountain pen, the first coding unit mounted on the housing near the writing end with the possibility of coding movement ball stop along the X axis direction and generating the corresponding signals, a second coding unit mounted on the housing near the recording end of the cylindrical housing with the possibility of coding a ball stop along the direction of the Y axis and generating the corresponding signals and character recognition means located in the cylindrical body and electrically connected to the first and second coding units with the possibility of receiving movement signals from them along the X axis and the Y axis and identifying the symbols formed on the surface for letters by means of a ball stop, based on these movement signals along the X axis and the Y axis, and generating computer codes that are associated with characters identified by this about the means.

 This device has a fairly compact size, but has a limited set of functions.

 The basis of the invention is the task of creating a computer that would be compact enough to be held in the hand and at the same time possess wide functionality - could be used both as a calculator, and as a control device for a telephone directory, and as an electronic dictionary, and as an electronic clock .

 The problem is solved in that a computer in the form of a fountain pen, containing an elongated cylindrical body having a writing end, equipped with a rotating ball rest serving as a writing station of a fountain pen, the first coding unit mounted on the housing near the writing end with the possibility of coding the movement of the ball stop along the direction axis X and generating the corresponding signals, a second coding unit mounted on the housing near the recording end of the cylindrical housing with the possibility of coding movement a ball stop along the direction of the Y axis and generating the corresponding signals, and character recognition means located in the cylindrical body and electrically connected to the first and second coding units with the possibility of receiving movement signals from them along the X axis and the Y axis and identifying characters generated on the surface for writing by means of a ball stop, based on these movement signals along the X axis and Y axis, and generating computer codes that are associated with the characters identified by this The means according to the invention further comprises a telephone directory accumulation unit located in the cylindrical body of the fountain pen, for accumulating a telephone directory database therein and a telephone directory management tool located in the cylindrical structure of the fountain pen and associated with a means of recognizing characters formed on the writing surface and corresponding name and contact phone number associated with this name, and with the accumulation unit of the telephone directory, moreover, The telephone directory is configured to work in the accumulation mode of the telephone directory so that it processes computer codes that are associated with characters identified by the character recognition means in order to determine the name and contact phone number corresponding to these computer codes, and to accumulate the name and contact the telephone numbers thus defined in the accumulation unit of the telephone directory, and / or the mouse mode operation unit located in the cylindrical body of the pen and electrically connected to the first and second encoding nodes for receiving movement signals from them along the X and Y axes, and a communication unit located in a cylindrical body and electrically connected to the mouse mode operation unit, which is configured to allow the communication unit to communicate with the computer, and / or a keyboard mode operation unit located in the cylindrical body of the fountain pen and connected to character recognition means for receiving computer codes from it, and a communication unit located in the cylindrical sensor body and electrically connected with the work unit in the keyboard mode, the unit works in keypad mode is configured to permit communication unit to communicate with the computer.

 In another embodiment, the computer further comprises an output device mounted on the pen body, and an output driver unit located in the pen body and connected to the output device, the character recognition means being operatively connected to the output driver block so that the indicated output device can indicate symbols, identified by character recognition.

 Preferably, the output device is an indicator device for visually indicating characters identified by the character recognition means.

 In this case, the computer further comprises an electronic clock means located in the housing, automatically operatively connected to the output driver unit so that the output device can initiate an output signal of the electronic clock means.

 It is desirable that the computer additionally contains an audio signal generator installed in the cylindrical body of the pen connected to the electronic clock means and controlled by it so that an output alarm sound is generated when the electronic clock determines that its time output coincided with a predetermined alarm time.

 It is advisable to equip the computer with a computing tool located in the cylindrical body of the fountain pen and associated with a means of recognizing characters formed on the writing surface corresponding to an arithmetic expression configured to process computer codes that are associated with characters identified by means of character recognition, in order to to calculate the results of an arithmetic expression.

 In this case, it is possible that the calculation tool was operatively connected with the output driver block so that the hopeless device would indicate the result of an arithmetic expression.

 It is desirable that the output device is an indicator unit for visual indication of the result of an arithmetic expression.

 Preferably, the computer is equipped with a dictionary database located in the cylindrical body of the pen for accumulating information about the words of the language and a search tool in the dictionary located in the cylindrical body of the pen and associated with the character recognition means and the database of the dictionary, the search tool in the dictionary configured to process computer codes that are associated with characters identifiable by the character recognition means and determine a word corresponding to computer codes, ahozhdeniya information corresponding to the word that defines the database dictionary.

 In this case, it is desirable that the search tool in the dictionary be additionally operatively connected with the output driver unit with the possibility of the output device indicating the information obtained by the search tool in the dictionary from the dictionary database.

 It is advisable that the management of the telephone directory was made with the possibility of working in search mode in the telephone directory by processing computer codes that are associated with identifiable characters using a character recognition tool to determine the name corresponding to the computer codes and search in the accumulation unit of the telephone directory for determining the contact phone number associated with this name.

 In this case, it is possible to operatively associate the telephone directory management tool with the output driver unit so that the output device could indicate the contact telephone number obtained by the telephone directory management tool from the telephone directory storage unit.

 Preferably, the output device is a display unit.

 It is advisable to equip the computer with an ink supply means located in the cylindrical body of the pen to supply ink to the ball stop.

 It is also possible that each of the coding units contains a frame element mounted on the writing end of the cylindrical body of the fountain pen, a rotating axis mounted rotatably on the frame element, a contact element fixed on the rotating axis and in contact with the ball stop so that the rotation of the ball the stop can cause a corresponding rotation of the rotating axis, a rotating element mounted on a rotating axis for joint rotation with it, and a reading unit mounted on a frame element with by issuing movement signals in response to the movement of the rotating element.

 It is desirable that the rotating element was made as a conductive element having a central part of the installation mounted on a rotating axis and a plurality of equally spaced contact legs protruding radially outward from the central part of the installation, the rotary element being made with the possibility of electrical connection with a voltage source, and the reading unit includes an insulating substrate and front and rear conductive plates mounted respectively on the front and rear the sides of the insulating substrate, and the insulating substrate is mounted on the frame element near the rotating element so that the rotation of the rotating axis in the first direction allows the contact legs to sequentially come into contact with the front conductive plate and the rotation of the rotating axis in the opposite second direction allows the contact legs to sequentially enter into contact with back conductive plate.

 In addition, it is possible for the rotating element to have a central part of the apparatus fixed to the rotary axis and a plurality of equally spaced shading legs that protrude radially outward from the central part of the apparatus, and the reading unit includes first and second photodetectors mounted on the side of the frame element and in the vicinity of the rotating member such that rotating the rotating axis in the first direction allows each of the shading legs to shade the first photodetector before the second photodetector is shaded a tector, and rotating the rotary axis in the opposite second direction allows each of the shading legs to obscure the second photodetector before the first photodetector is obscured.

 It is advisable that the first and second photodetectors be phototransistors.

 The rotating element had a central part of the installation, mounted on a rotating axis, and a plurality of legs located at the same distance, which protrude radially outward from the central part of the installation, each of the legs having a permanent magnet located on it, and the reading unit includes the first and second sensors, operating according to the principle of the Hall effect, mounted on the frame element on the side and near the rotating element so that the rotation of the rotating axis in the first direction allows each of the legs to be close the specified first sensor operating according to the principle of the Hall effect, before it passes close to the specified second sensor working according to the principle of the Hall effect, and rotation of the rotating axis in the opposite second direction allows each of the legs to be close to the specified second sensor working on the principle Hall effect before it passes close to the specified first sensor, working on the basis of the Hall effect.

 In a preferred embodiment, the mouse mode operation unit allows the communication unit to transmit movement signals along the X axis and the Y axis for reception by a computer.

 In this case, the movement signals along the X axis and the Y axis control the movement of the cursor on the computer screen.

 In another preferred embodiment, the keyboard mode operation unit is adapted to permit the communication unit to transmit computer codes for reception by a computer.

 In a most preferred embodiment, the communication unit is an infrared communication unit.

Other features and advantages of the present invention will become apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings, in which
FIG. 1 is a schematic fragment of a writing unit according to a first preferred embodiment of a computer in the form of a fountain pen in accordance with the present invention;
FIG. 2 is a coding unit in accordance with a first preferred embodiment;
FIG. 3 shows the relative position of the coding units and the ball bearing in accordance with the first preferred embodiment;
FIG. 4 is a rotating element and a reading unit of an encoding unit in accordance with a first preferred embodiment;
FIG. 5 is a schematic diagram of the interdependence of movement signals coming from coding units and the direction of movement of the ball stop in accordance with the first preferred embodiment;
FIG. 6 is a timing chart illustrating movement signals coming from coding units according to a first preferred embodiment when the movement of the ball stop occurs only in the + Y direction;
FIG. 7 is a timing chart illustrating movement signals coming from coding units according to a first preferred embodiment when the movement of the ball stop occurs both in the “-Y” direction and in the “+ X” direction;
FIG. 8 is a timing chart illustrating movement signals coming from coding units according to a first preferred embodiment when the movement of the ball stop occurs only in the + X direction;
FIG. 9 is a schematic cross-sectional view of a fragment of a cylindrical body of a fountain pen in accordance with a first preferred embodiment;
FIG. 10 is a block diagram of a control device in accordance with a first preferred embodiment;
FIG. 10A is a block diagram of a storage device included in the control device of FIG. 10;
FIG. 10B is a block diagram of a processor of the control device shown in FIG. 10;
FIG. 11 is a flowchart illustrating a flowchart of a first preferred embodiment;
FIG. 12 is a flowchart illustrating the operation of a processor according to a first preferred embodiment in a computing mode;
FIG. 13 is a schematic illustration of a rotating element and a reading unit of an encoding assembly in accordance with a second preferred embodiment of a computer in the form of a pen in accordance with the present invention;
FIG. 14 is a schematic illustration of a rotating element and a reading unit of an encoding assembly in accordance with a third preferred embodiment of a computer in the form of a pen in accordance with the present invention.

 Consider FIG. 1, which shows a first preferred embodiment of a fountain pen computer 1 in accordance with the present invention, which comprises an elongated cylindrical fountain pen housing 10 having a writing end formed with an axial hole 11 and a pair of right-angled radial chambers that are connected to the hole 11 through the cutouts 12, 13. The rotating ball stop 15 protrudes outward from the cylindrical body 10 of the pen through the axial hole 11 and serves as the writing unit 16 of the ball pen. An ink rod-shaped ink supply unit 14 is located in a cylindrical pen body 10 and supplies ink to the ball stop 15. In a preferred embodiment, the ball stop 15 is rotatably held at one end of the ink supply unit 14. The first and second coding units 2, 2 'are mounted respectively in radial chambers at the writing end of the cylindrical body 10 of the fountain pen. The first coding unit 2 encodes the movement of the ball stop 15 in the direction of the X axis and generates movement signals along the X axis corresponding to the encoded movement of the ball stop 15 in the direction of the X axis. The second coding unit 2 'encodes the movement of the ball stop 15 along the direction of the Y axis and generates movement signals along the Y axis, corresponding to the encoded movement of the ball stop 15 along the direction of the Y axis.

 Referring to FIG. 1-4, it can be seen that both the first and second coding units 2, 2 ′ include a frame element 22 fixedly mounted in respective radial chambers at the writing end of the cylindrical body 10 of the fountain pen. Rotating axis 220 is rotatably mounted on frame member 22. Ball-shaped contact elements 20, 21 are mounted on a rotating axis 220 and enter the cylindrical body of the pen 10 through the cutouts 12, 13 so that they are in contact with the ball stop 15 so that the rotation of the ball stop 15 in a certain direction can transmit rotation on the rotary axis 220. The elements 20, 21 are in contact with the ball stop 15, located at right angles to each other, as best shown in FIG. 3. The rotating element 23 is fixed on the rotating axis 220 so that it rotates with it. The reading unit 24 is fixed to the frame element 22 for generating movement signals in accordance with the determined movement of the rotating element 23.

 Thus, when the cylindrical body 10 of the fountain pen is held with one hand while forming 15 characters on the writing surface through the ball stop, the contact elements 20, 21 rotate in accordance with the direction of movement of the ball stop 15 to transmit rotation to the corresponding rotating axis 220 and the associated rotating element 23. Movement signals along the X-axis and Y-axis are sequentially and accordingly generated by the reading blocks 24 of the first and second coding units 2, 2 'in accordance with the determined movement with the corresponding rotating element 23.

In a first preferred embodiment, the rotatable member 23 is formed as a conductive member having a center portion 232 of the apparatus that is mounted on the rotary axis 220 and a set of equally spaced contact legs 230 that protrude radially outward from the center portion 232 of the apparatus. The rotating member 23 is electrically connected to a first terminal of a voltage source, such as an earth terminal of a power supply. The reader unit 24 includes an insulating substrate 241 mounted on the frame member 22 near the rotating member 23, and front and rear conductive plates 240, 242 mounted respectively on the front and rear sides of the insulating substrate 241. The front and rear conductive plates 240, 242 are electrically connected to the second terminal of the voltage source, such as the positive (or V _CC ) terminal of the power supply. When the contact elements 20, 21 are rotated due to the rotation of the ball stop 15 in the direction corresponding to the first direction of movement, the contact legs 230 are connected in series with the front conductive plate 240, which leads to the generation of movement signals along the + X and + Y axes. Accordingly, when the contact elements 20, 21 rotate in a direction corresponding to the second direction of movement due to the rotation of the ball stop 15, the contact legs 230 sequentially come into contact with the rear conductive plate 242, which leads to the generation of motion signals along the axes -X and -Y .

The relationship between the movement signals coming from the first and second coding units 2, 2 ′ and the direction of movement of the ball stop 15 is shown in FIG. 5. Below we give three conditional examples to illustrate the operation of coding nodes 2, 2 ':
1. In the state (+ Y> X = 0) shown in FIG. 5, the movement of the ball stop 15 occurs only in the + Y direction. In this case, the contact element 20 is stationary, while the element 21 rotates in the first direction. In FIG. 6 shows movement signals along the X and Y axes generated by the first and second coding nodes 2, 2 ′ in the state (+ Y> X = 0). In addition, in FIG. 6 shows that since the contact element 20 is fixed, the corresponding rotating element 23 does not rotate, thus leaving the front and rear conductive plates 240, 242 in a state of high logic level, due to the connection of the latter with the positive (or V _CC ) terminal block nutrition. On the other hand, since the contact element 21 rotates in the first direction, the corresponding rotating element 23 rotates so that the contact leg 230 contacts in series with the front conductive plate 240. Since the rotary element 23 is electrically connected to the ground terminal of the power supply, the logical state of the front the conductive plate 240 changes from a high to a low logic level, for example, at the moment when one of the contact legs 230 comes into contact with it. Thus, due to the rotation of the rotating element 23 with the contact element 21 in the first direction, the movement signal along the + Y axis from the second coding unit 2 'is generated in the form of a pulse train, which in this mode is a pulse located at the same time intervals.

 In the example of FIG. 6, displacement signals along the + Y axis from the first coding unit 2 ′ are formed as nine consecutive pulses. The number of signal pulses when moving in the + Y direction from the second coding unit 2 'depends on the speed of the ball stop 15 in the + Y direction. The faster the movement of the ball stop 15 in the + Y direction, the narrower the pulses in the movement signal along the + Y axis from the second coding unit 2 ', and the number of pulses in the movement signal along the + Y axis will be large.

 The rotation speed of the contact elements 20, 21 depends on the vector angular component of the movement of the ball stop 15, which acts on the corresponding contact elements 20, 21. For example, when the vector angular components acting on the contact elements 20, 21 are equal, the contact elements 20, 21 rotate at the same speed. When the vector angular component acting on the contact element 20 is larger than the component acting on the element 21, the contact element 20 rotates at a faster speed than the contact element 21. Accordingly, when the vector angular component acting on the contact element 20 is smaller than the component acting on the contact element 21, the contact element 20 will rotate at a lower speed compared to the contact element 21.

 2. In the state (-Y = + X) shown in FIG. 5, the movement of the ball stop 15 occurs both in the -Y direction and in the + X direction. In this case, the contact element 20 rotates in the first direction, while the contact element 21 rotates in the second direction. In FIG. 7 shows the movement signals along the X and Y axes generated by the first and second coding nodes 2, 2 'in the state (-Y = + X). As can be seen, both the movement signal along the + X axis and the movement signal along the -Y axis from the first and second coding units 2, 2 'are a sequence of pulses. However, since the vector angular components of movement of the ball stop 15, which act on the contact elements 20, 21, are equal, suggesting that the ball stop 15 moves at the same speed as in the example shown in FIG. 6, the contact elements 20, 21 rotate at a lower speed compared to the example shown in FIG. 6, which thus leads to wider pulses of movement signals along the + X axis and along the -Y axis.

 3. In the state (+ Y = 0 <X) shown in FIG. 5, the movement of the ball stop 15 occurs only in the + X direction. As a result of this, the contact element 21 will be stationary, while the contact element 20 will rotate in the first direction. In FIG. Figure 8 shows the movement signals along the X and Y axes generated by the first and second coding nodes 2, 2 'in the state (+ Y = 0 <X). As can be seen, the movement signal along the Y axis from the second coding unit 2 ′ remains at a high logical level all the time, while the movement signal along the X axis from the first coding unit 2 is a sequence of pulses.

 In FIG. Figure 9 shows that the cylindrical case of the fountain pen 10 also has a mounting hole 17. A part of the mounting frame 18 extends inwardly and is integrally connected to the cylindrical body of the fountain pen in close proximity to the mounting hole 17. The electronic panel 37 is mounted on the mounting frame 18 and is located on it control unit 3.

 In FIG. 10, the control unit 3 includes a power unit 31, a storage device 32, a processor 33, an output device 34, an audio signal generator 35, a set of 36 switches, and a wireless communication unit 38, such as a conventional infrared communication unit.

 The power supply unit 31 can be made in the form of series-connected battery cells (not shown) and supplies the device with the electrical energy necessary for the operation of the control device 3.

 In FIG. 10A, a memory device 32 is provided that includes at least a computer code storage area 321, a dictionary database area 322, a telephone directory data storage area 323, and a calculation area 324. The computer code storage area 321 is used to accumulate character patterns and associated standard computer codes, which are mapped to characters formed on the writing surface through a ball stop 15. One example of a standard computer code is ASCII (American Standard Code for Information Interchange) (American Standard Code for Information Interchange)), which is suitable for encoding alphanumeric characters. However, based on the fact that in some languages, such as Chinese and Japanese, ASCII code is not used for character encoding, in area 321 more than one type of character patterns and standard computer codes can accumulate so that computer 1 can work as a fountain pen in formats of various languages. Area 322 of the dictionary database is used to accumulate information about the words of the language. The information may be the meaning of a word or a translation of a word into another language, for example, from English to Chinese. For accumulation in the dictionary database area 322, known dictionary databases in electronic form of the aforementioned type are applicable. The telephone directory accumulation area 323 is used to accumulate a telephone directory database therein. The format of the telephone directory storage area 323 may be similar to that used by most conventional portable electronic devices such as electronic dictionaries and personal digital assistants. Area 324 calculations is used for temporary storage of data during the calculation, the identification of the input symbol, the formation of the record entered in the database of the telephone directory, etc.

 In a preferred embodiment, the storage device 32 is performed using two different types of storage devices. The first storage device is a flash memory (FLASH) having at least a computer code storage area 321, a dictionary database area 322, and a telephone directory storage area 323. The second storage device is an electrostatic random access memory having at least a computing region 324.

 Presented by FIG. 10, the output device 34 is preferably made in the form of a liquid crystal indicator (LCD) unit, which is mounted in the mounting hole 17 of the cylindrical body 10 of the pen. The audio signal generator 35 is implemented as a speaker and a set of 36 switches is used to control the operating modes of the processor 33, as will be described in more detail in the following description.

 As shown in FIG. 10 and 10B, a processor 33, for example a microprocessor, is connected to a power supply unit 31, a storage device 32, an output device 34, an audio signal generator 35, a set of 36 switches and a wireless communication unit 38. The processor 33 is furthermore connected to the first and second coding units 2, 2 ′ (see FIG. 1) so that it can receive movement signals from them along the X and Y axis. In FIG. 10B, the processor 33 is designed in such a way that it contains a character recognition unit 331, an electronic clock unit 332, a calculation unit 333, a dictionary search unit 334, a telephone directory management unit 335, an output driver unit 336, a mode operation unit 338 "mouse" and block 339 work in keyboard mode.

 In FIG. 11 is a flowchart illustrating the operation of the first embodiment of the preferred embodiment. Considering, in addition, FIG. 1, 10, 10A and 10B, it can be seen that when the power supply 31 is turned on, the set of 36 switches can be used in a predetermined manner so as to select the operating mode of the processor 33 and the working language of computer 1 in the form of a fountain pen. When the ball stop 15 moves along the writing surface to form characters, the first and second coding units 2, 2 'will generate movement signals along the X and Y axes corresponding to the detected movement of the ball stop 15. In this case, the character recognition unit 331 will read the corresponding character patterns and standard computer codes from the computer code storage area 321 of the storage device 32 and store the same information in the computing area 324 so that calculations can be made and compared I have to identify the characters formed on the writing surface, and the development of computer codes that are associated with identifiable so characters. The generated computer codes of the identified characters are stored in the area 324 calculations. The character recognition means 331 is further operatively coupled to the output driver unit 336, which allows the output device 34 to indicate the characters identified by the character recognition means 331.

 As for the method for recognizing characters identified by means of recognizing characters that are formed on the writing surface through the ball stop 15, this operation can be performed using known character recognition techniques that vary depending on the language of the characters being identified.

 When using computer 1 in the form of a pen to calculate the result of an arithmetic expression, first, a set of 36 switches is used in such a way as to ensure the operation of the processor 33 in the calculation mode. When the characters that make up the arithmetic expression are recorded on the writing surface through the ball stop 15, the character recognition means 331 operates so that computer codes of the identified characters are stored in the calculation area 324. The computation unit 333 then processes the computer codes recorded by the character recognition means 331 to calculate the result of the arithmetic expression. This action is enabled when the computer code for the "=" sign is recognized.

 Block 333 calculations, in addition, is operatively connected with the block 336 of the output driver, which allows the output device 34 to indicate the result of an arithmetic expression.

 In FIG. 12 is an algorithm illustrating the operation of the processor 33 in the computing mode. Since the functions associated with the processor 33, when operating in this mode, are similar to the functions of conventional calculators, a detailed explanation of the algorithm depicted in FIG. 12 will be omitted for brevity.

 When using computer 1 in the form of a fountain pen to search for information relating to a specific word, a set of 36 switches will initially be used to switch the processor 33 to search mode in the dictionary. When the characters that make up a particular word are recorded on the writing surface through the ball stop 15, the character recognition means 331 will transmit the identified characters to a computing area 324 for recording computer codes. The dictionary search unit 334 then processes the computer codes recorded by the character recognition means 331 in order to determine the word corresponding to the computer codes, and finds information corresponding to the word that was thus determined in the dictionary database area 322 of the storage device 32. This the action can be included after determining the character corresponding to the computer code "?", which is added to the characters of the corresponding word. The dictionary search unit 334 is additionally operatively connected with the output driver unit 366, which allows the output device 34 to display information received by the dictionary search unit 334 from the dictionary database area 334.

 As is known in the art, the procedure for determining a word by computer codes differs depending on the selected working language of computer 1 in the form of a fountain pen. Since the search procedure associated with the dictionary search unit 334 is common for electronic dictionaries, a detailed description thereof will be omitted for brevity.

 A set of 36 switches can be activated, in addition, in such a way as to switch the processor 33 into the telephone directory management mode. In the telephone directory management mode, the name and associated contact telephone number can be added to the telephone directory storage area 323 and the contact phone number that is associated with the entered name can be obtained from the telephone directory storage area 323. When adding an entry to the telephone directory accumulation area 323, the characters that make up the name and the telephone contact number associated with this name are recorded on the writing surface through the ball stop 15. The character recognition unit 331 stores computer codes for the identified symbols in the computing area 324, as described above. The telephone directory control unit 335 then transmits the computer codes recorded by the character recognition means 331 to determine the name and contact telephone number corresponding to these computer codes. The telephone directory control unit 335 is also operably connected to the output driver unit 336, which allows the output device 34 to display the name and contact number determined by the telephone directory control unit 335 for verification. After confirming the accuracy of the information displayed on the output device 34, using a set of 36 switches, the telephone directory control unit 335 records the name and contact number as a new input entry in the telephone directory storage area 323.

 When searching for a contact number in the telephone directory accumulation area 323, the characters that make up the input name are written on the writing surface through the ball stop 15. The character recognition means 331 accumulates computer codes for the identified symbols in the calculation area 324, and the telephone directory control unit 335 then transmits computer codes stored by character recognition means 331 for the purpose of determining an input name corresponding to these computer codes. When adding a character, such as "?", To the input name, the telephone directory management unit 335 is turned on in the symbol detection mode in the telephone directory storage area 323 to search for a contact number that is associated with the input name. Using the output driver block 336, the output device 34 is turned on to indicate the input name and associated contact number obtained by the telephone directory control unit 335.

 Since the well-known technologies for constructing telephone directories and searching in telephone directories used in portable electronic devices are applicable to the telephone directory control unit 335, a more detailed description of the latter will be omitted here for the purpose of brevity.

 A set of 36 switches can then be activated to turn the processor 33 into clock mode. In clock mode, the 332-hour electronic unit is turned on to generate a time output. The electronic clock block 332 is operatively coupled to the output driver block 336 so that the output device 34 can display the time signal of the electronic clock block 332. As in a conventional electronic clock, using the set of 36 switches when turning it on in a predetermined manner while the processor 33 is in clock mode, you can set the output time of the electronic clock block 332 and the alarm time. In addition, at a time when the electronic clock unit 332 determines that the output time has reached a predetermined time to turn on the alarm, the electronic clock unit 332 in a known manner includes an audio signal generator 35 in order to turn on the alarm output.

 A set of 36 switches can be further used in such a way that it turns the processor 33 into mouse mode. In mouse mode, the mouse operation unit 338 receives motion signals along the X and Y axes from the first and second coding units 2, 2 ′. Then, the mouse operation unit 338 controls the operation of the wireless communication unit 38 for establishing, in a known manner, wirelessly with the computer 4 so as to transmit movement signals along the X and Y axes without wires for reception by the computer 4 through the corresponding standard communication unit 40 (SBS). Thus, the movement signals along the X and Y axes can be used to control the cursor on the screen (not shown) of computer 4. A set of 36 switches in this case works similar to the switches located on a regular computer mouse. When the switch set 36 is activated, the mouse operation unit 338 controls the wireless communication unit 38 so that corresponding switch signals are transmitted to the computer 4.

 The set of switches 36 may, in addition, be activated so that it enables the operation of the processor 33 in keyboard mode. In keyboard mode, the keyboard operation unit 339 receives computer codes generated by the character recognition means 331. At the same time, the keyboard operation unit 339 controls the wireless communication unit 38 so as to establish a wireless connection with the computer 4, while the computer codes are wirelessly transmitted to the computer 4 through the standard communication unit 40 (SBS), thereby allowing the computer 1 to work as a fountain pen in as a character input device to the computer 4. The computer 1 in the form of a pen in accordance with the present invention, thus, facilitates the input of characters of complex languages such as Chinese.

 Consider again FIG. 10 and 10B of the preferred embodiment, in which the processor 33 further includes a power control unit 337 that is operatively connected to the storage device 32 so that when the power supplied to the computer 1 in the form of a fountain pen is turned off, or when the remaining energy in the power supply unit 31 is insufficient to ensure the normal operation of the control device 3, the power management unit 337 will transmit data such as the name and the corresponding contact phone number from the electrostatic random access memory to hydrochloric type flash memory in order to avoid data loss.

 The configuration of the first and second coding nodes should not be limited to that described above. In the computer in the form of a pen in accordance with the present invention, other configurations of coding units may be used, as shown in FIG. 13 and 14.

 In FIG. 13 depicts a rotating element 23a and a reading unit 24a of an encoding unit according to a second preferred embodiment of a computer in the form of a pen in accordance with the present invention. The rotary member 23a is made of plastic and has a center portion 232a that is mounted on a rotating axis (not shown) and a plurality of equally spaced shading legs 230a that extend radially from the center portion 232a of the setup. The reading unit 24a includes first and second photodetectors (T1), (T2), such as phototransistors mounted on a frame element (not shown) on the side and in close proximity to the rotating element 23a.

 When the rotating axis rotates in the first direction, each of the shading legs 230a shades the first photodetector (T1) before the second photodetector (T2) is shaded. Thus, the movement signal from the first photodetector (T1) will go into a high logical state before it is changed on the second photodetector (T2). When the rotating axis rotates in the opposite direction, each of the shading legs 230a shades the second photodetector (T2) before the first photodetector (T1) is shaded. Thus, the movement signal from the second photodetector (T2) will change to a high logical state before the state of the first photodetector (T1) is changed. When the rotating axis will not rotate, the first and second photodetectors (T1), (T2) will not be obscured by the shading legs 230a, and will not generate the corresponding movement signal, which will be maintained at a low logic level.

 In FIG. 14 shows a rotating element 23b and a reading unit 24b of an encoding unit according to a third preferred embodiment of a computer in the form of a fountain pen in accordance with the present invention. The rotating member 23b has a center portion 232b mounted on a rotating axis (not shown) and a plurality of equally spaced legs 230b that protrude radially outward from the center portion 232b of the setup. Each of the legs 230b is provided with a permanent magnet. Preferably, each of the legs 230b is formed of a material having the properties of a permanent magnet. The reading unit 24b includes first and second sensors (S1), (S2), operating on the basis of the Hall effect, mounted on a frame element (not shown) on the side and near the rotating element 23b. When the rotating axis rotates in the first direction, each of the legs 230b moves near the first sensor (S1) operating according to the principle of the Hall effect before it passes near the second sensor (S2) operating according to the principle of the Hall effect. Thus, the movement signal from the first sensor (S1) will change to a high logical state before the signal of the second sensor (S2) changes. When the rotating axis rotates in the opposite direction, each of the legs 230b will move near the second sensor (S2) operating according to the principle of the Hall effect before it passes near the first sensor (S1) operating according to the principle of the Hall effect. Thus, the movement signal from the second sensor (S2) will change to a high logical state before the signal of the first sensor (S1) changes. When the rotating axis does not rotate, the first and second sensors (S1), (S2), operating according to the principle of the Hall effect, will not be affected by the magnetic field of the legs 230b and will not generate the corresponding movement signals, i.e. they will be maintained in a low logical state.

 While the present invention has been described in terms of considering the most practical and preferred embodiments, it is understood that the present invention is not limited to the described embodiments, but is intended to cover various arrangements, within the spirit and scope of the present invention in their broadest interpretation as so that all such modifications and equivalent arrangements are covered.

Claims (23)

 1. A computer in the form of a fountain pen, containing an elongated cylindrical body having a writing end, equipped with a rotating ball rest serving as a writing station of a fountain pen, a first coding assembly mounted on the housing near the writing end with the possibility of coding the movement of the ball stop along the X axis direction and generating corresponding signals, a second coding unit mounted on the housing near the recording end of the cylindrical housing with the ability to encode the movement of the ball stop along the direction the Y axis and generating the corresponding signals, and character recognition means located in a cylindrical body and electrically connected to the first and second coding nodes with the possibility of receiving movement signals from them along the X axis and the Y axis and identifying the characters formed on the writing surface by means of a ball stop based on these movement signals along the X-axis and the Y-axis and the generation of computer codes that are associated with the characters identified using this tool, characterized in that it additionally contains a telephone directory accumulation unit located in the cylindrical case of the pen, for accumulating a telephone directory database therein, and a telephone directory management tool located in the cylindrical structure of the pen and associated with a means of recognizing characters formed on the surface for writing and corresponding to the name and contact the phone number associated with this name, and with the accumulation unit of the telephone directory, and the telephone directory management tool It is possible to work in the accumulation mode of the telephone directory so that it processes computer codes that are associated with characters identified by the character recognition means, in order to determine the name and contact phone number corresponding to these computer codes, and to accumulate the name and contact number in a telephone directory accumulation unit, and / or a mouse mode operation unit located in the cylindrical body of the pen and electrically connected to the first and second coding units for To receive movement signals from them along the X and Y axes, and a communication unit located in a cylindrical body and electrically connected to the mouse mode operation unit, which is configured to allow the communication unit to communicate with the computer, and / or the operation unit in keyboard mode located in the cylindrical case of the fountain pen and connected to the character recognition means for receiving computer codes from it, and a communication unit located in the cylindrical case and electrically connected to the keyboard mode key Aturi, wherein in the keyboard mode of operation block configured to allow communication unit to communicate with the computer.  2. The computer according to claim 1, characterized in that it further comprises an output device mounted on the pen body, and an output driver unit located in the pen body and connected to the output device, the character recognition means being operatively connected to the output driver block, which allows the specified output device to display the characters identified by the character recognition means.  3. The computer according to claim 2, characterized in that the output device is an indicator device for visual indication of the characters identified by the character recognition means.  4. The computer according to claim 3, characterized in that it further comprises an electronic clock means located in the case, automatically operatively connected to the output driver unit so that the output device can indicate the time signal output of the electronic clock means.  5. The computer according to claim 4, characterized in that it further comprises an audio signal generator installed in the cylindrical case of the pen, connected to the electronic clock means and controlled by it so that an audio output alarm is generated when the electronic clock determines that its time output coincided with a predefined alarm time.  6. The computer according to any one of paragraphs. 2-5, characterized in that it further comprises a computing tool located in the cylindrical body of the pen and associated with a means of recognizing characters formed on the writing surface corresponding to an arithmetic expression configured to process computer codes that are associated with characters identified by character recognition means, in order to calculate the results of an arithmetic expression.  7. The computer according to claim 6, characterized in that the calculation tool is operatively connected to the output driver unit so that the output device can indicate the result of an arithmetic expression.  8. The computer according to claim 7, characterized in that the output device is an indicator unit for visual indication of the result of an arithmetic expression.  9. The computer according to any one of paragraphs. 2-8, characterized in that it is further provided with a database of the dictionary located in the cylindrical body of the pen for accumulating information about the words of the language and a search tool in the dictionary located in the cylindrical body of the pen and associated with the means of character recognition and the database of the dictionary, moreover, the search in the dictionary is configured to process computer codes that are associated with characters identifiable by the character recognition means and determine a word corresponding to computer codes, finding information corresponding to a word determined from a dictionary database.  10. The computer according to claim 9, characterized in that the search tool in the dictionary is additionally operatively connected to the output driver unit with the ability to indicate with the output device information obtained by the search tool in the dictionary from the dictionary database.  11. The computer according to any one of paragraphs. 2-10, characterized in that the control tool for the telephone directory is configured to operate in search mode in the telephone directory by processing computer codes that are associated with identifiable characters using character recognition means to determine the name corresponding to the computer codes and search in the block accumulating a telephone directory to determine the contact phone number associated with this name.  12. The computer according to claim 11, characterized in that the telephone directory management tool is operatively connected to the output driver unit so that the output device can display the telephone contact number obtained by the telephone directory management tool from the telephone directory storage unit.  13. A computer according to claim 10 or 12, characterized in that the output device is a display unit.  14. The computer according to any one of the preceding paragraphs, characterized in that it further comprises an ink supply means located in the cylindrical body of the pen for supplying ink to the ball stop.  15. The computer according to any one of the preceding paragraphs, characterized in that each of the coding nodes contains a frame element mounted on the writing end of the cylindrical body of the fountain pen, a rotating axis mounted rotatably on the frame element, a contact element mounted on a rotating axis and located in contact with the ball stop so that the rotation of the ball stop can cause the corresponding rotation of the rotating axis, a rotating element mounted on the rotating axis for joint rotation with it, and count ayuschy unit mounted on frame member to output a movement signal in response to movement of the rotating member.  16. The computer according to p. 15, characterized in that the rotating element is made as a conductive element having a Central part of the installation, mounted on a rotating axis, and many equally spaced contact legs protruding radially outward from the Central part of the installation, and rotating the element is made with the possibility of electrical connection with a voltage source, and the reading unit includes an insulating substrate and front and rear conductive plates mounted respectively on the days and the back sides of the insulating substrate, and the insulating substrate is mounted on the frame element near the rotating element so that the rotation of the rotating axis in the first direction allows the contact legs to come into contact with the front conductive plate in series and rotation of the rotating axis in the second, second direction allows the contact legs make contact with the rear conductive plate in series.  17. The computer according to p. 15, characterized in that the rotating element has a central part of the installation, mounted on a rotating axis, and a plurality of equally spaced shading legs that protrude radially outward from the central part of the installation, and the reading unit includes first and second photodetectors mounted on the frame element on the side and near the rotating element so that the rotation of the rotating axis in the first direction allows each of the shading legs to shade the first photo detector before it is shaded the second photodetector, and rotation of the rotating axis in the opposite, second, direction allows each of the shading legs to obscure the second photodetector before the first photodetector is obscured.  18. The computer according to claim 17, characterized in that the first and second photodetectors are phototransistors.  19. The computer according to p. 15, characterized in that the rotating element has a Central part of the installation, mounted on a rotating axis, and many equally spaced legs that protrude radially outward from the Central part of the installation, each of the legs has a permanent magnet located on it, and the reading unit includes first and second sensors operating according to the principle of the Hall effect, mounted on the frame element on the side and near the rotating element so that the rotation of the rotating axis in the first direction Allows each of the legs to be close to the specified first sensor working according to the principle of the Hall effect, before it passes close to the specified second sensor that works according to the principle of the Hall effect, and rotation of the rotating axis in the opposite, second direction allows each of the legs to be close from the indicated second sensor operating according to the principle of the Hall effect, before it passes close to the specified first sensor operating according to the principle of the Hall effect.  20. The computer according to any one of the preceding paragraphs, characterized in that the mouse mode operation unit allows the communication unit to transmit movement signals along the X axis and the Y axis for reception by the computer.  21. The computer according to claim 20, characterized in that the movement signals along the X axis and Y axis control the movement of the cursor on the computer screen.  22. A computer according to any one of the preceding paragraphs, characterized in that the keyboard mode operation unit is adapted to permit the communication unit to transmit computer codes for reception by a computer.  23. The computer according to any one of the preceding paragraphs, characterized in that the communication unit is an infrared communication unit.

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